Incased Tethered Magnet, Method and System for Securing Bottles in Arm&#39;s Reach

ABSTRACT

An encased tethered magnet, system and method for securing a bottle in arm&#39;s reach are disclosed. A substantially oblong flux enhanced magnet may comprise a flux enhancing layer and a magnetic layer. A tether encases the magnet. The tether has a first end configured to suspend the magnet proximal an inside wall of the bottle and a second end configured to extend beyond a bottle opening. The method for securing the bottle includes tethering the magnet proximal a side wall, a bottom wall or a top wall of the receptacle and placing the magnet within an attracting distance to a magnetically attractive surface to secure it thereto. The system includes a retainer comprising at least one magnetically attractive device affixed thereon to attach to the tethered magnet through the bottle and an optional scratch-inhibiting material. The retainer is configured to attach to a user&#39;s pants pocket, clothing item or tool.

BACKGROUND OF THE INVENTION

There is a need for the ability to secure any shape of bottle or fromtipping over and spilling. Window washers and car detailers to name afew, may especially appreciate having their cleaning liquids andchemicals secure when washing high rise office building windows ordetailing SUVs, boats and campers and other large vehicles. Conventionalbottle holders are typically designed to conform to the outside contourof cylindrical bottles but fall short of being able to securerectangular drink boxes, oblong spray bottles and other odd shaped fluidreceptacles.

There is also a need to be able to conveniently store any shape offrequently used bottle or fluid receptacle not only to save shelf spacebut to save a user from the back ache of bending over to reach bottlesstored in lower shelves in cabinets and closets. Furthermore, there is aneed for a way of securing any type of beverage such as a drink box orwater bottle to a hiker or sports enthusiast. Many conventional drinkcup holders are not adaptable to secure a rectangular drink box, an ovaltype canteen or water bag to a hiker's gear or outfit. Therefore, thereis a need for an aftermarket consumer and service device, method andsystem adaptable to any type of fluid receptacle.

SUMMARY OF THE INVENTION

An encased tethered magnet, system and method for securing a bottle inarm's reach are disclosed. A substantially oblong flux enhanced magnetcomprises a flux enhancing layer and a magnetic layer. A tether encasesthe magnet. The tether has a first end configured to suspend the magnetfrom one end proximal an inside wall of the bottle and a second tetherend is configured to extend beyond a bottle opening. The encasedtethered magnet therefore enables securing any shape and size of bottleor fluid receptacle to a metallic or magnetically attractive surface.

A method for securing a fluid receptacle, including drink cups, drinkboxes, cleaning bottles, squeeze bottles, spray bottles, buckets, cans,canisters, drums and all other fluid receptacles regardless of shape orsize in arm's reach, is disclosed. The method includes tethering asubstantially oblong magnet proximal an inside wall of a fluidreceptacle where an inside wall may be a side wall, a bottom wall or anoptional top wall of the receptacle. The method further includessecuring the fluid receptacle to a magnetically attractive surface byplacing the magnet within an attracting distance to the surface. Anembodiment of the method includes securing a fluid receptacle to ametallic surface using an encased electro-magnet tethered by at leastone wire in communication with the electro-magnet.

Additionally, a system for securing a fluid receptacle to a metallicsurface in arm's reach and to a user's pocket or other clothing item orto any other pocketed, recessed and substantially vertical surface isdisclosed. The system includes a substantially oblong flux enhancedmagnet comprising a flux enhancing layer sandwiched between a pluralityof magnetic layers. The system also includes a deformable tetherencompassing the magnet, the tether configured to suspend the magnetfrom one end against an inside wall of the bottle and to deform betweenthe bottle and a cap secured to the bottle at an opening thereof. Thesystem further includes a retainer comprising at least one magneticallyattractive device or magnetically attractive surface affixed thereto.The magnetically attractive device or surface is configured to attach tothe oblong magnet through the bottle. The retainer is configured toattach to a user's pants pocket or another clothing item or a tool.Embodiments of the disclosed system also comprise a scratch inhibitingmaterial sandwiched between the bottle and the metallic surface.

Other aspects and advantages of embodiments of the disclosure willbecome apparent from the following detailed description, taken inconjunction with the accompanying drawings, illustrated by way ofexample of the principles of the disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a front elevation of an encased tethered magnet inaccordance with an embodiment of the present disclosure.

FIG. 2 depicts a side elevation of the encased tethered magnet inaccordance with an embodiment of the present disclosure.

FIG. 3 depicts a cross-section through 3-3 of the encased tetheredmagnet of FIG. 1 in accordance with an embodiment of the presentdisclosure.

FIG. 4 depicts a perspective view of an encased tethered magnet asdisposed in a bottle opening in accordance with an embodiment of thepresent disclosure.

FIG. 5 depicts a perspective view of an encased tethered magnet asdisposed inside a capped squeeze bottle in accordance with an embodimentof the present disclosure.

FIG. 6 depicts a perspective view of an encased tethered magnet asdisposed inside a capped spray bottle in accordance with an embodimentof the present disclosure.

FIG. 7 depicts a perspective view of an encased tethered magnet disposedinside a capped bottle for securing the bottle to a metallic surface inaccordance with an embodiment of the present disclosure.

FIG. 8 depicts a perspective view of a system for securing a bottle to ametallic surface through a scratch-inhibiting material in accordancewith an embodiment of the present disclosure.

FIG. 9 depicts a retainer comprising a magnetically attractive deviceattached thereto in accordance with an embodiment of the presentdisclosure.

FIG. 10 depicts a side elevational view of the retainer as seen from theright side of FIG. 8 in accordance with an embodiment of the presentdisclosure.

FIG. 11 depicts the retainer attached to the encased tethered magnetthrough the bottle to secure the retainer to the bottle and enable auser to secure the bottle to a user's pocket in accordance with anembodiment of the present disclosure.

FIG. 12 depicts the encased tethered magnet securing a squeeze bottleonto an electric rotary buffer via a belt attached to a magneticallyattractive device in accordance with an embodiment of the presentdisclosure.

FIG. 13 is a flow chart of a method of securing a fluid receptacle to ametallic surface in arm's reach via an encased tethered magnet thereinin accordance with an embodiment of the present disclosure.

FIG. 14 is a flow chart of a method of securing a fluid receptacle to ametallic surface in arm's reach via an encased tethered electro-magnettherein in accordance with an embodiment of the present disclosure.

Throughout the description, similar reference numbers may be used toidentify similar elements.

DETAILED DESCRIPTION

Reference will now be made to exemplary embodiments illustrated in thedrawings and specific language will be used herein to describe the same.It will nevertheless be understood that no limitation of the scope ofthe disclosure is thereby intended. Alterations and furthermodifications of the inventive features illustrated herein andadditional applications of the principles of the inventions asillustrated herein, which would occur to one skilled in the relevant artand having possession of this disclosure, are to be considered withinthe scope of the invention.

Applications and advantages of the disclosure may include securingwindow washing fluid bottles to scaffolding and other equipment andsecuring window washing fluid bottles directly to high rise buildingscomprising metallic exteriors. Window washers therefore have theircleaning fluids conveniently within arms' length. Also, car detailersmay be able to secure detailing fluid bottles within arms' reach securedon the vehicles being detailed and avoid setting the bottles on theground between use. Detailers may also easily secure detailing fluids totheir equipment such as rotary buffers as explained herein. Therefore,accidents tripping over and spilling bottles may be avoided or entirelyeliminated. Additionally, metal walls at storage facilities suddenlybecome walls of depository for cleaning fluids saving shelf, cabinet andcloset space for other vertically oriented tools such as shovels, rakes,brooms and the like. The disclosed retainer clip may also be used inconjunction with the disclosed encased and tethered magnet to providemeans for securing camping gear to sports enthusiasts, securing drinkbottles to hikers and securing medications to refrigerators and thelike.

FIG. 1 depicts a front elevation of an encased tethered magnet inaccordance with an embodiment of the present disclosure. The encasedtethered magnet includes a tether 1 and a magnet 2. A tether first end 3is configured to encase the magnet and to suspend the magnet proximal aninside wall of the bottle. A second end 4 is configured to extend beyonda bottle opening.

In an embodiment of the disclosure, the tether 1 may fully encase themagnet 2. The tether 1 depicted is only representative of an embodimentand other tether shapes and configurations comprising all the functionalcharacteristics of the tethers depicted and disclosed are therefore alsoimplicitly claimed herein. The tether 1 may comprise a fluid-inhibitingor water-proof material. The tether may also comprise a washablematerial for insertion into drink bottles and drink cups. The tether 1may be configured in a substantially thin ribbon-like shape having alength greater to an elongate length of the bottle. The tether 1 mayalso be configured to deform between the bottle and a cap secured to abottle opening to enable a liquid tight seal there between. The tether 1may comprise cloth, rubber, silicone and other low durometer plasticsand materials which allow the magnet 2 to freely suspend within thebottle from the bottle mouth or opening.

The encased magnet 2 may be a substantially oblong flux enhanced magnetcomprising at least one flux enhancing layer and at least one magneticlayer as detailed below in FIG. 3. The encased magnet 2 may comprisesingle or multiple hybrid magnetic materials. The encased magnet 2 maybe configured to pass through the mouth or opening of most bottles andtherefore be oblong and elongate and may also be cylindrical. Theencased magnet 2 may also comprise electro-magnetic configurations andmaterials.

FIG. 2 depicts a side elevation of the encased tethered magnet inaccordance with an embodiment of the present disclosure. The visualappearance of the magnet 2 may be determined by the contour of thetether material 1 encasing it. The tail end 4 of the tether may be verythin relative to its length and therefore enable it to deform betweenthe threads of a bottle and a cap placed thereon. The encased magnet 2is substantially elongate to maximize the surface area magneticallyexposed to a metallic surface in proximity to the bottle and yet allowthe encased magnet to be tethered inside bottles having small diameteropenings.

FIG. 3 depicts a cross-section through 3-3 of the encased tetheredmagnet of FIG. 1 in accordance with an embodiment of the presentdisclosure. Layers 2 a and 2 c may be magnetic and layer 2 b may be aflux enhancing layer. The flux enhancing layer 2 b provides a conduitfor the magnetic flux from the magnet 2 and thus enhances the magneticproperties of the magnet. The magnet 2 may comprise multiple magneticlayers and multiple flux enhancing layers where the flux enhancinglayers may be sandwiched between the magnetic layers. The magneticlayers may comprise neodymium magnetic materials and any other permanentor semi-permanent magnetic materials. The flux enhancing layers maycomprise iron and other metallic materials which are conductive tomagnetic flux. Embodiments of the flux enhanced magnet 2 may beconfigured in an oblong and semi-cylindrical shape, a polygonal shapeand any other shape having an elongate dimension to more easily slipthrough a narrow bottle mouth and maximize magnetic surface area.

FIG. 4 depicts a perspective view of an encased tethered magnet asdisposed in a bottle opening in accordance with an embodiment of thepresent disclosure. FIG. 4 illustrates the flexible and deformablenature of the tether which enables the encased magnet 2 to be freelysuspended from the bottle opening. The encased magnet 2 is thereforeable to freely move to any inside wall of the bottle according tomagnetic attraction forces to a metallic surface in proximity to thebottle and the magnet. The elongate tether 1 may also allow the encasedmagnet 2 to touch any inside wall of the bottle, including the top andbottom walls. Though the bottle depicted includes a top wall adjacentthe bottle opening, bottles having no top wall (not depicted) such asdrink cups and glasses are also securable to metallic surfaces via theencased tethered magnet, method and system as disclosed.

Though the bottle depicted in FIG. 4 is cylindrical, the disclosedencased tethered magnet, method and system therefore perform equallywell in relation to drink cups, drink boxes, cleaning bottles, squeezebottles, spray bottles, buckets, cans, canisters, drums and any otherfluid receptacles regardless of shape or size and material of therespective receptacle. Also, the disclosure is not limited to open fluidreceptacles or to closed receptacles.

FIG. 5 depicts a perspective view of an encased tethered magnet asdisposed inside a capped squeeze bottle in accordance with an embodimentof the present disclosure. Embodiments of the disclosure include cappedand uncapped bottles, drink cups and fluid receptacles. The tether 1 isconfigured to deform and conform between the threads of the bottleopening and the cap so that a liquid tight seal may be formed therebetween. The tether 1 may therefore be freely tethered from a cappedbottle or from an uncapped bottle as depicted in FIG. 4 and explainedabove.

FIG. 6 depicts a perspective view of an encased tethered magnet asdisposed inside a capped spray bottle in accordance with an embodimentof the present disclosure. Embodiments of the disclosure claim thebottle as part of the disclosed system for securing a fluid receptacleas discussed below with respect to FIG. 8. The tether 1 encasing themagnet 2 may be adjusted at the mouth of the bottle to hang anywhere upand down or from side to side in the bottle to enable the bottle to beflat and adjacent a metal surface. The placement of the magnet 2 in FIG.6 disposes the magnet 2 just below a constricting ridge 5 in the spraybottle and thus provides a mechanical advantage against gravity pullingthe bottle downward and away from the metallic surface. Spray bottles ofcounter top cleaning and sterilizing fluid may thus be stored in arm'sreach on the side of a refrigerator or freezer using the encased andtethered magnet.

FIG. 7 depicts a perspective view of an encased tethered magnet disposedinside a capped bottle for securing the bottle to a metallic surface inaccordance with an embodiment of the present disclosure. It is to beunderstood that throughout the present disclosure that the term‘metallic surface’ is synonymous with ‘magnetically attractive surface.’This lexicography is necessary because not all metallic surfaces arenecessarily magnetically attractive. Aluminum and copper for instanceare weakly magnetically attractive where iron and steel are stronglyattractive. The encased magnet 2 is depicted in a side view elevation toillustrate the attraction of the magnet 2 to the metallic surfacevertically disposed. In other words, the magnet 2 is naturally attractedalong its broadest surface area in relation to the metallic surface. Themagnet 2 may still secure the bottle to the metallic surface along anyof its sides but may secure the bottle with maximum magnetic attractionat its broadest surface area.

FIG. 8 depicts a perspective view of a system for securing a bottle to ametallic surface through a scratch-inhibiting material in accordancewith an embodiment of the present disclosure. The system includes abottle 6 with a cap 7 secured thereon, a substantially oblong fluxenhanced magnet 2 comprising at least one flux enhancing layersandwiched between a plurality of magnetic layers and a deformabletether 1 encompassing the magnet. The tether 1 may be configured tosuspend the magnet 2 from one end against an inside wall of the bottle 6and to deform between the bottle 6 and the cap 7 secured to the bottleat an opening thereof. The disclosed bottle securing system may furthercomprise a scratch inhibiting material 8 sandwiched between the bottleand the metallic surface. The scratch inhibiting material protects themetallic surface from scratches incident to moving the bottle after ithas been secured to the metallic surface via the encased and tetheredmagnet. The scratch inhibiting material 8 may therefore comprisenon-abrasive materials such as leather, cotton, silk, and the like alsocomprising synthetic materials and blends.

FIG. 9 depicts a retainer comprising a magnetically attractive deviceattached thereto in accordance with an embodiment of the presentdisclosure. The disclosed system may include a retainer 9 configured asa bracket or clip comprising at least one magnetically attractive deviceor surface 10 affixed thereto. Where the retainer inherently orotherwise comprises a magnetically attractive surface, a separatemagnetically attractive device may not be necessary. The clip 9 maycomprise metallic materials or any other rigid and semi-rigid materials.The clip 9 may be configured in an upside-down ‘J’ or ‘U’ or ‘V’configurations and like configurations to enable hanging the clip from auser's pocket or other clothing item. The magnetic device 10 isconfigured to attach to the oblong magnet 2 through the bottle 6 and maytherefore comprise magnetic and metallic materials.

FIG. 10 depicts a side elevational view of the retainer as seen from theright side of FIG. 9 in accordance with an embodiment of the presentdisclosure. The width and thickness of the magnetically attractivedevice 10 may be similar or the same as the width and thickness of theencased and tethered magnet 2 in order to maximize the attraction therebetween. The magnetically attractive 10 device may be disposedmechanically on the retainer clip or bracket 9 or it may be magneticallydisposed thereon.

FIG. 11 depicts the retainer attached to the encased tethered magnetthrough the bottle to secure the retainer to the bottle and enable auser to secure the bottle to a user's pocket in accordance with anembodiment of the present disclosure. The retainer bracket or clip 9 maybe configured to either mechanically attach to a user's clothing item orto hang from a user's pocket. The scratch inhibiting material 8 may notbe necessary when the clip 9 is secured to the bottle 6 via the magnet2.

FIG. 12 depicts the encased tethered magnet securing a squeeze bottleonto an electric rotary buffer via a belt attached to a magneticallyattractive device in accordance with an embodiment of the presentdisclosure. The belt or strap 11 is secured tightly around the electricrotary buffer and the magnetically attractive device or surface 10 isattached thereto mechanically or by a hook and loop arrangement or thelike. The fluid from the bottle 6 may therefore drip out under the forceof gravity or be otherwise forced out of the cap 7 and onto a worksurface at the control of the user while the squeeze bottle is securedto the buffer in an upside-down position. The rotary pads of the buffer13 may therefore buffer a surface lubricated by the fluid from thebottle 6. The user may hold the buffer at the handles 14 and 15 and nothave to hold the squeeze bottle while operating the rotary buffer. Thisembodiment also allows a user to quickly release the buffer fluid bottlefrom the buffer for refilling without removing the retainer belt orstrap. This embodiment also has the advantage over hook and loop typeattachments which wear out over time because the magnetic bond betweenthe encased tethered magnet and a magnetically attractive surface willnot wear out nor diminish over time and use.

Embodiments of FIG. 12 may include systems and methods for securing afluid receptacle onto other tools and equipment requiring constant orperiodic fluid or lubricant. The disclosed encased and tethered magnet,method and system for securing a bottle in arm's reach is thereforeparticularly advantageous for aftermarket applications to cutting toolsrequiring water lubrication onto a cutting surface and constant oillubrication onto moving parts.

A further embodiment of the disclosure includes a fluid receptaclesecuring electro-magnet and system further comprising at least oneelectrical wire in communication with the electro-magnet. The deformabletether encompassing the electro-magnet may therefore also encompass theat least one wire. The tether may be configured to suspend the magnetfrom one end proximal an inside wall of the receptacle and to deformbetween the receptacle and a cap secured to the receptacle at an openingthereof and yet allow the at least one wire access outside thereceptacle.

FIG. 13 is a flow chart of a method of securing a fluid receptacle to ametallic surface in arm's reach via an encased tethered magnet thereinin accordance with an embodiment of the present disclosure. The methodincludes tethering 110 a substantially oblong magnet proximal an insidewall of a fluid receptacle, the magnet comprising at least one fluxenhancing layer and at least one magnetic layer. The method alsoincludes attaching 120 the fluid receptacle to a metallic surface inarm's reach by placing the magnet within an attracting distance to themetallic surface.

An embodiment of the disclosed method may comprise tethering an oblongmagnet at one end proximal an inside wall of the receptacle to a capsecured to the receptacle and attaching the receptacle to the metallicsurface by placing the magnet within an attracting distance to thesurface.

Another embodiment of the disclosed method may further comprisesandwiching a scratch-inhibiting material between the receptacle and themetallic surface. The embodiment may also comprise leaving a portion ofthe tether outside the capped receptacle for retrieving the magnet fromthe bottle in order to remove the secured bottle from the metallicsurface.

FIG. 14 is a flow chart of a method of securing a fluid receptacle to ametallic surface in arm's reach via an encased and tetheredelectro-magnet therein in accordance with an embodiment of the presentdisclosure. The method includes tethering 130 a substantially oblongelectro-magnet proximal an inside wall of a fluid receptacle, the tethercomprising at least one wire therein in communication with theelectro-magnet. The method also includes powering-up 140 theelectro-magnet. The method additionally includes attaching 150 the fluidreceptacle to a metallic surface in arm's reach by placing theelectro-magnet within an attracting distance to the metallic surface.The method further includes powering-down 160 the electro-magnet inorder to move the receptacle or to remove the receptacle.

An embodiment of the disclosed method may include tethering an oblongelectro-magnet at one end proximal an inside wall of the receptacle to acap secured to the receptacle, powering-up the electro-magnet andattaching the receptacle to the metallic surface by placing theelectro-magnet within an attracting distance to the metallic surface.

Although the operations of the method(s) herein are shown and describedin a particular order, the order of the operations of each method may bealtered so that certain operations may be performed in an inverse orderor so that certain operations may be performed, at least in part,concurrently with other operations. In another embodiment, instructionsor sub-operations of distinct operations may be implemented in anintermittent and/or alternating manner.

And though specific embodiments of the invention have been described andillustrated, the invention is not to be limited to the specific forms orarrangements of parts so described and illustrated. The scope of theinvention is to be defined by the claims and their equivalents to beincluded by reference in a non-provisional utility application.

1. A fluid receptacle securing magnet, comprising: a substantiallyoblong magnet; and a tether encompassing the magnet, a tether first endconfigured to suspend the magnet from one end proximal an inside wall ofa bottle and a second end configured to extend beyond a bottle opening.2. The fluid receptacle securing magnet of claim 1, wherein the oblongmagnet comprises at least one flux enhancing layer adjacent at least onemagnetic layer and may therefore comprise one flux enhancing layersandwiched between multiple magnetic layers.
 3. The fluid receptaclesecuring magnet of claim 2, wherein the magnetic layers may compriseneodymium magnetic materials and any other permanent and semi-permanentmagnetic materials.
 4. The fluid receptacle securing magnet of claim 2,wherein the flux enhancing layer comprises iron and other metallicmaterials conductive to magnetic flux.
 5. The fluid receptacle securingmagnet of claim 1, wherein the oblong magnet is further configured in asemi-cylindrical shape, a polygonal shape and any other shape having anelongate dimension.
 6. The fluid receptacle securing magnet of claim 1,wherein the tether comprises a fluid-inhibiting and water-proofmaterial.
 7. The fluid receptacle securing magnet of claim 1, whereinthe tether is configured in a substantially thin ribbon-like shapehaving a length greater to an elongate length of the bottle.
 8. Thefluid receptacle securing magnet of claim 1, wherein the tethercomprises a low durometer material and is configured to deform betweenthe bottle and a cap secured to a bottle opening to enable a liquidtight seal therebetween.
 9. The fluid receptacle securing magnet ofclaim 1, wherein the magnet is an electro-magnet and the tethercomprises at least one wire in communication with the electro-magnet,the at least one wire configured to supply power and control to theelectro-magnet.
 10. A method for securing a fluid receptacle, the methodcomprising: tethering a substantially oblong magnet at one end proximalan inside wall of the receptacle to a cap secured to the receptacle; andattaching the receptacle to a metallically attractive surface in arm'sreach by placing the magnet within an attracting distance to thesurface.
 11. The method for securing a fluid receptacle of claim 10,further comprising sandwiching a scratch-inhibiting material between thereceptacle and the metallically attractive surface.
 12. The method forsecuring a fluid receptacle of claim 10, further comprising leaving aportion of the tether outside the capped receptacle for retrieving themagnet from the bottle.
 13. The method of securing a fluid receptacle ofclaim 10, wherein the magnetically attractive surface is attached to abelt and the like and the belt is attached to a work tool.
 14. Themethod of securing a fluid receptacle of claim 13, further comprisingforcing and otherwise allowing fluid from the bottle onto a workingsurface while operating the tool, the bottle being secured to the worktool via the magnetically attractive surface and the encased tetheredmagnet.
 15. The method for securing a fluid receptacle of claim 10,further comprising: tethering a substantially oblong electro-magnet atone end proximal an inside wall of the receptacle to a cap secured tothe receptacle; powering-up the electro-magnet; attaching the receptacleto the magnetically attractive surface by placing the electro-magnetwithin an attracting distance to the surface; and powering-down theelectro-magnet in order to move the receptacle.
 16. A bottle securingsystem, comprising: a substantially oblong flux enhanced magnetcomprising a flux enhancing layer and a magnetic layer; and a deformabletether encompassing the magnet, the tether configured to suspend themagnet from one end against an inside wall of the bottle and to deformbetween the bottle and a cap secured to the bottle at an openingthereof; and a retainer comprising at least one magnetically attractivedevice affixed thereto, the magnetically attractive device configured toattract to the oblong magnet through the bottle, the retainer configuredto attach to an item.
 17. The bottle securing system of claim 16,further comprising a scratch inhibiting material sandwiched between thebottle and a magnetically attractive surface.
 18. The bottle securingsystem of claim 16, wherein the retainer is configured in an upside-down‘J’ configuration and the like to enable hanging the bottle from auser's pocket.
 19. The bottle securing system of claim 16, wherein theretainer is configured in a clip to mechanically attach to a user'sclothing item.
 20. The bottle securing system of claim 16, wherein theretainer is configured as a belt and the like, the belt configured totightly encircle a tool and secure the bottle to the tool via the magnetand the magnetically attractive device.